CZ23864U1 - Distance section for distance section frame for insulation window unit and insulation window unit per se - Google Patents

Abstract

A spacer profile (50) for a spacer profile frame mountable in the edge area of an insulating window unit for forming an intervening space (53) between window panes (51, 52), has a profile body (10) made of synthetic material and comprises one or more chambers (20) for accommodating hygroscopic material. A metal film (30) encloses the profile body on three-sides such that, in the bent/assembled state of the spacer profile, the non-enclosed inner side of the profile body is directed towards the intervening space between the window panes. The not-enclosed inner side of the profile body comprises openings (15) for moisture exchange between hygroscopic material accommodated in the chamber(s) and the intervening space between the window panes. The metal film comprises a profile (31a-g, 32a-g) on each end directed towards the intervening space of the window panes. Each profile has at least one edge or bend.

Description

Cross-reference

This application claims priority from US Provisional Application No. 60/608,221 filed September 9, 2004, the contents of which are incorporated herein by reference.

Technical field

The technical solution relates to spacers and insulating window units which use spacers according to the technical solution.

BACKGROUND OF THE INVENTION

Insulating window units having at least two window panes which are kept at a distance from one another in the insulating window unit are known. Insulating windows are normally made of inorganic or organic glass or other materials such as Plexiglas. The spacing of the window panes is normally provided by a spacer frame (see reference numeral 50 in FIG. 1). The spacer frame is either assembled from several pieces by means of connectors or is bent from a single piece (see FIG. 2), in which case the spacer frame 50 needs to be closed by connector 54 in only one position.

Different designs are used for insulating window units to provide good thermal insulation. In one construction, the interspace between the sheets is preferably filled with an inert, insulating gas, such as argon, krypton, xenon, and the like. Obviously, the gas charge must not be allowed to escape from the interspace between the sheets. Therefore, the space between the plates must be sealed. Moreover, it is also clear that nitrogen, oxygen, water, etc. contained in the ambient air must not be allowed to enter the space between the plates. Therefore, the spacer profile must be designed to prevent such diffusion. When the term "diffusion impermeability" is used in the following description in relation to spacers and / or spacer materials, this term includes both vapor diffusion impermeability and gas diffusion impermeability.

Furthermore, the heat transfer through the edge joints, i.e. in particular the joints in the frame of the insulating window unit, the window pane joints and the spacer frame, plays an important role in achieving low heat conduction through these insulating window units. Insulating window units, which are perfectly insulated along the edge joint, meet the condition of a "warm edge", a term used in the art.

Spacers are usually made of metal. However, such metal spacers are not able to meet the "warm edge" condition. Therefore, in order to improve such metal spacers, metal spacers provided with a synthetic material have been described, eg in US 4,222,213 or DE 102 26 268 A1.

Although it is expected that a spacer consisting solely of synthetic material would satisfy the "warm edge" condition, it would be difficult to satisfy the requirements for diffusion tightness and strength.

Other known solutions include spacers made of synthetic material which are provided with a metal foil as a diffusion barrier and a reinforcing layer, as shown, for example, in EP 0 953 715 A2 (member of the US patent family 6,192,652) or EP 1 017 923 (member of the patent family) US 6,339,909).

Such composite spacers use a profile body made of synthetic material and provided with a metal foil, which should be as thin as possible to meet the "warm edge" condition, but on the other hand should have a minimum thickness to ensure diffusion-tightness and strength.

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Since metal is a significantly better heat conductor than synthetic material, attempts have been made to design a thermal bridge between the side edges / walls of the spacer profile (i.e., through the metal foil) as long as possible (see EP 1 017 923 A1).

In order to improve the gas impermeability, the spacer is preferably bent from a single piece of the spacer profile, if possible, so cold (at a room temperature of about 20 ° C) where only one location is created which can potentially deteriorate the impermeability. between respective ends of the bent spacer frame. To close and seal this gap, a connector is fastened to the bent spacer.

When the spacer profile is bent, especially when using cold bending techniques, wrinkles are formed in the bends (see Figure 3c), which is a problem. On the other hand, the advantage of cold bending is, as mentioned above, the excellent diffusion impermeability and the extended service life of the insulating window unit.

According to the solution described in EP 1 017 923 A1, the problem of wrinkle formation can be solved well, but the space available in the drying material chamber is not satisfactory, in particular due to the small distance between the plates, i.e. a separation distance of less than 12 mm. for spacing 6, 8 or 10 mm. According to other solutions such as those shown, for example, in FIG. 1 in EP 0 953 715 A2, the problem of wrinkle formation, in particular in bends, persists. In both solutions, however, there is a problem of considerable deflection of unsupported, long portions of the spacer profile when the spacer profile is to be used in a large frame (see Figs. 3a and 3b).

A composite spacer profile is also known from EP 0 601 488 A2 (a member of the US patent family 5,460,862), where a reinforcement is embedded in the side of the profile which faces the interspace between the tables in the assembled state.

The essence of the technical solution

The object of the present invention is to provide improved spacer profiles that advantageously meet the " warm edge " condition and reduce wrinkle problems while maximizing the volume of the desiccant chamber. The secondary objectives of the invention are improved methods for producing such spacer profiles and an improved insulating window unit with such spacer profiles.

One or more of these objectives addresses a technical solution defined by independent claims.

Further developments of the technical solution are given by dependent claims.

According to this technical solution, the spacer profile may advantageously comprise a profile body made of synthetic material. Preferably, one or more chambers for storing the hygroscopic material are defined in the profile body. Preferably, the metal foil substantially or completely surrounds the profile body on three sides, e.g. on the outside and the two side walls of the profile. In addition, the metal foil preferably has a thickness sufficient to serve as a gas / vapor impermeable (substantially diffusion resistant or substantially diffusion resistant) layer. When the spacer profile is bent into the spacer frame and positioned between the two window panes, the side (eg, inner) of the profile body that is not covered with a metal foil is preferably arranged to point into the space between the two window panes of the insulating window unit.

In addition, the non-sealed (metal-free) inner side of the profile body preferably comprises openings and / or one or more materials adapted to facilitate moisture exchange between the hygroscopic material, which is preferably housed in the chamber (s) when the spacer is in the final assembled state. and the space between the window panes.

In addition, each end of the metal foil (diffusion barrier) preferably comprises a profile (or an elongated portion) which is formed to adjoin respective side walls near the inner side of the spacer profile and which in a bent / assembled state will point into the interspace between the window panes. . The profile (s) or elongate portion (s) may preferably include at least one edge, corner portion and / or bend. In preferred embodiments, the profile (s) may be raised

To define the rim to the portion of the metal foil that covers or is located on the side wall of the profile body.

Such spacers can advantageously be used as spacers which can be fixed along the edge area of the insulating window unit and which form and secure the space between the 5 panes. Thus, the invention also relates to insulating window units comprising at least two window panes and one or more spacer profiles described herein.

When the spacers include the aforementioned metal profiles, the deflection of the unsupported, elongated portions of the spacers will preferably be smaller, preferably significantly smaller, especially when using a spacers for large frames.

If the profile or elongated portion has a bent, corner and / or folded configuration, the length (in cross-section perpendicular to the direction of the longitudinal direction) of the profile or elongated portion and hence the diffusion barrier foil material additionally added in this region or region of the spacer profile magnify. As a result, the fold line is shifted, which further leads to less wrinkle formation. Furthermore, the deflection is considerably less since the bent, corner and / or folded profile / elongated portion imparts significant strength to the structural integrity of the bent spacer.

Other features and objects will be apparent from the description of the exemplary embodiments with reference to the figures.

BRIEF DESCRIPTION OF THE DRAWINGS

Figures 1a) and b) show, in perspective, cross-sections through a configuration of the window panes of an insulating window unit, in which a spacer profile, an adhesive material and a sealing material are arranged between the panes.

Fig. 2 shows a side view, partially in section, of a spacer frame bent from a spacer profile in an ideal state.

Fig. 3a) shows a side view, partially in section, of a spacer frame bent from a spacer profile in real condition, showing the deflection (downward or downward deformation) between the imaginary supports on the upper crossbar; Fig. 3b) shows an imaginary test arrangement; and Fig. 3c) shows fold formation.

Figures 4a) and 4b) show cross sections of a spacer profile according to the first embodiment in the W-configuration and the U-configuration.

Figures 5a) and 5b) show cross sections of a spacer profile according to the second embodiment in a W30 configuration and a U-configuration.

Figures 6a) and 6b) show cross sections of a spacer profile according to the third embodiment in the W-configuration and the U-configuration; Fig. 6c) shows an enlarged view of the portion delimited by the circle in Fig. 6a) and Fig. 6d) shows an enlarged view of the portion delimited by the circle in Fig. 6b).

7a) and 7b) show cross sections of a spacer profile according to a fourth embodiment in a W35 configuration and a U-configuration.

Figures 8a) and 8b) show cross sections of a spacer profile according to a fifth embodiment in the W-configuration and the U-configuration.

Figures 9a) and 9b) show cross sections of a spacer profile according to a sixth embodiment in the W-configuration and the U-configuration.

Figures 10a) and 10b) show cross sections of a spacer profile according to a comparative example (ie not having a profiled elongated portion) in the W-configuration and the U-configuration; and Fig. 10c) shows a table with the values for the spacer profiles of Figs. 4 to 10 obtained in the test arrangement of Fig. 3.

Figures 11a) and 11b) show cross sections of a spacer profile according to a seventh embodiment in a 45 W-configuration and a U-configuration.

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Fig. 12 shows a table representing the results of the evaluation of the behavior of the spacer profiles according to Figs.

Examples of technical solution

Embodiments of the invention are described in detail below with reference to the figures. The same 5 characters / elements are denoted by the same reference numerals in all figures. However, for the sake of clarity, not all reference numerals are inserted in all figures. The three-dimensional system (X, Y, Z) shown in FIG. 1, between FIGS. 5 and 6 and between FIGS. 8 and 9, applies to all figures, all description and all claims. The longitudinal direction corresponds to the Z direction, the transverse direction corresponds to the X direction and the height direction corresponds to the Y direction.

In Figures 1, 4 to 9 and 11, in each of the views a) the so-called W-configuration is shown and in each of the views b) the so-called U-configuration. Referring now to Figs. 4a) and 4b), a spacer profile according to the first embodiment will be described.

In Figures 4a) and 4b), the spacer profile is shown in a cross-section perpendicular to the longitudinal direction, i.e. in the X-Y plane, and with this constant cross-section extends in the longitudinal direction. The spacer 15 has a height h1 in the height direction and comprises a profile body 10 which is formed of a first material. The first material is preferably an elastically-plastically deformable, poorly heat-conducting (insulating) material.

The term "elastically-plastically deformable" as used herein preferably means that elastic forces are active in the material after the bending process, which seeks to restore the state prior to bending, which is typically the case for synthetic materials in which only part of the bending is plastic, irreversible deformation. Furthermore, the term "poorly conductive" preferably means that the thermal conductivity coefficient λ is less than or equal to about 0.3 W / (mK).

The first material is preferably a synthetic material, more preferably a polyolefin and even more preferably polypropylene, polyethylene terephthalate, polyamide or polycarbonate. An example of such a polypropylene is Novolen ® 1040K. The first material preferably has a modulus of elasticity of less than or equal to about

2200 N / mm ² and a thermal conductivity coefficient λ of less than or equal to about 0.3 W / (mK), more preferably less than or equal to about 0.2 W / (mK).

The body 10 is profiled firmly bonded (e.g. by fusion and / or gluing) to the one-piece diffusion barrier film 30. The diffusion barrier film 30 is formed of a second material. Preferably, the second material is a plastically deformable material. The term " plastically deformable " here is preferably understood to mean that the elastic forces are practically non-existent in the material after the deformation. This is typical, for example, for metals bent beyond the elastic limit (apparent yield strength). The second material is preferably a metal, more preferably stainless steel or a steel with a tin (e.g., tin coating) or zinc corrosion protection steel. If necessary or desired, a chromium or chromate train can be applied to the material.

As used herein, the term "rigidly bonded" preferably means that the profile body 10 and the diffusion barrier film 30 are permanently connected to each other, for example by co-extruding the profile body with the diffusion barrier film and / or applying adhesive material if necessary. The bonding strength is preferably sufficiently high so that the materials in the tear test according to DIN 53282 do not split 40.

Furthermore, the diffusion barrier foil is additionally preferably acting as a reinforcing element. Its thickness (material thickness) d1 is preferably less than or equal to about 0.30 mm, more preferably less than or equal to 0.20 mm, even more preferably less than or equal to 0.15 mm, even more preferably less than or equal to 0.12 mm and even more preferably less than or equal to 0.10 mm. In addition, the thickness d1 is preferably greater than or equal to about 0.10 mm, more preferably greater than or equal to 0.08 mm, even more preferably greater than or equal to 0.05 mm, and even more preferably greater than or equal to 0.03 mm. The maximum thickness is selected to match the desired heat conduction value. The thinner the film, the better it is met

-4GB 23864 U1 hot edge condition. Preferably, each of the embodiments shown in the figures has a thickness in the range 0.05 mm to 0.13 mm.

A preferred material for the diffusion barrier film is steel and / or stainless steel having a thermal conductivity coefficient λ of less than or equal to about 50 W / (mK), more preferably less than or equal to 5 about 25 W / (mK) and even more preferably less than or equal to about 15 W / (mK). The modulus of elasticity of the second material preferably falls within the range of about 170 to 240 kN / mm ² and is preferably about 210 kN / mm ² . The breaking elongation of the second material is preferably greater than or equal to about 13%, more preferably greater than or equal to about 20%. An example of a stainless steel foil is a steel foil of material 1.4301 or 1.4016 according to DIN EN 10 08812 having a thickness of 0.05 mm, and an example of a tin foil is an foil made of Anthracty E2, 8/2, 8T57 having a thickness of 0.125 mm .

Further details of the materials that can advantageously be used according to the invention are described in EP 1 017 923 A1 / B1 (US 6,339,909), the contents of which are incorporated herein by reference.

The profile body 10 comprises an inner wall 13 and an outer wall 14 which are separated by a distance h2 in the height direction Y 15 and two side walls H, 12 which are separated by a certain distance in the transverse direction X and extend substantially in the height direction Y. the walls 11, 12 are connected by an inner wall 13 and an outer wall 14, thereby forming a chamber 20 for storing the hygroscopic material. The chamber 20 is defined on its respective sides in cross section by walls 11 to 14 of the profile body. The chamber 20 comprises a height h2 in the height direction Y. The side walls 11, 12 are formed as attachment bases for connection to the inner sides of the window panes. In other words, the spacer profile is preferably glued to the respective inner sides of the window panes via these attachment bases (see Fig. 1).

The inner wall 13 is defined here as the "inner" wall because in the assembled state of the spacer profile it is directed to the interspace between the window panes. This side of the spacer profile, which points towards the interspace between the window panes, is referred to in the following description as the inner side in the height direction of the spacer profile. The outer wall 14, which is arranged on the opposite side of the chamber 20 in the height direction Y, faces away from the interspace between the window panes in the assembled state and is thus defined herein as an "outer" wall.

In the W-configuration shown in Fig. 4a), both side walls 11, 12 comprise a concave portion, viewed from outside the chamber 20, which forms the transition of the outer wall 14 to the corresponding wall 11, 12. As a result, the thermal bridge is with the U-configuration shown in Fig. 4a) over the metal foil longer although the W- and U-configurations have the same height h1 and width b1. In contrast, the volume of the chamber 20, with the same width b1 and height h1, is slightly smaller.

Openings 15, 35 are formed in the inner wall 13, irrespective of the choice of material for the profile body, so that the inner wall 11 is not made impermeable. Moreover, or alternatively, in order to achieve the permeability of the structure, it is possible to select a material for the entire body of the profile and / or the inner wall that allows equivalent diffusion even without providing openings 15. However, creating openings 15 is a preferred solution. In any case, the moisture exchange between the window pane and the hygroscopic material is preferably provided in the chamber 20 in the assembled state (see also FIG. 1).

Those outer sides of the outer wall 14 and the side walls 11, 12 that face away from the chamber 20 are provided with a diffusion barrier foil 30. The film 30 extends along the side walls in the height direction Y up to the height h2 of the chamber 20. The one-piece diffusion barrier film 30 comprises at the ends of a profiled elongated portion 31, 32, each having a profile 31a, 32a.

As used herein, the term "profile" preferably means that the elongated portion is not solely a linear extension of the diffusion barrier film 30, but is a two-dimensional profile formed in a two-dimensional cross-sectional view in the XY plane, such profile being for example one or more bends; / or corners in the extended portion 31. 32.

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According to the embodiment shown in Fig. 4, the profile 31a, 32a comprises a bend (90 °) and a directly adjacent portion (flange), the portion (flange) extending in a length 11 in the transverse direction X from the outer edge of the corresponding side wall UL, 12 inwardly.

As regards the rigid connection of the profile body 10 and the diffusion barrier film 30, preferably at least one side of the diffusion barrier profile is firmly connected to the profile body 5. According to the embodiment shown in Fig. 4, the largest portion of the elongated portion is completely surrounded by the profile body material. The elongated portion is preferably located as close as possible to the inner wall of the spacer profile.

On the other hand, for purely aesthetic reasons, the diffusion barrier film should preferably not be visible through the window panes of the assembled insulating window unit. Therefore, the film should be covered on the inside and on the side with the profile body material. One embodiment in which the diffusion barrier film is visible will be described below with reference to Fig. 6.

In summary, the elongated portion should preferably be close to the inner side. Thus, the region of the profile body (storage region) in which the elongated portion is located (is supported) should preferably be clearly above the centerline of the profile in the height direction. In this case, the dimension (length) 15 of the receiving region from the inside of the spacer in the Y direction should not exceed more than% of the height of the spacer. In other words, the storage region 16, 17 comprises a height h3 in the height direction, wherein the height h3 should be less than or equal to about 0.4 hl, preferably less than or equal to about 0.3 hl, more preferably less than or equal to about 0, 2 hl and more preferably less than or equal to about 0.1 hl.

In addition, it is preferred that the weight (weight) of the elongate portion comprises at least about 10% of the weight (weight) of the remaining diffusion barrier film portion that is above the centerline of the spacer in the height direction, more preferably at least about 20%, more preferably at least about 50%. and even more preferably about 100%.

All details regarding the first embodiment also apply to all the other 25 described embodiments, except where the difference is openly mentioned or shown in the drawings.

Figures 5 a) and 5b) show, in cross-section in the X-Y plane, the spacer profile according to the second embodiment.

The second embodiment differs from the first embodiment in that the elongated portions 31, 32 are nearly twice as long as in the first embodiment, with the length 11 of the extension remaining the same. This is accomplished by including a second bend (180 °) in the profiles 31b, 32b and extending that portion of the elongated portion that connects to the other end, similarly in the transverse direction X but now outwards. This ensures a substantially longer length of the elongated portion while maintaining its maximum proximity to the inside of the spacer.

In addition, a portion of the profile body material is surrounded by the profile 31b, 32b on three sides. As a result of this closure 35, during the bending process, which involves compression, the material acts as a substantially incompressible bulk element.

6a) and 6b), the spacer profile according to the third embodiment will be described below, wherein the areas indicated in circles a) and b) are shown in detail in FIGS. 6c) and d). According to the embodiment shown in Fig. 6, the diffusion barrier film 30, including the elongated portions 31, 32, extends 40 all along the exterior of the profile body 10. Thus, the elongated portions 31, 32 and their profiles 31c, 32c are visible on the inside ("externally" facing the space between the window panes) in the assembled state, as the elongated portions 31, 32 are not covered on the inside by the profile body material; . According to this embodiment, the elongate portions are arranged as close to the inner side as possible.

The embodiment shown in Fig. 6 can be modified such that the elongated portion 31, 22 will be elongated and, like the embodiment shown in Fig. 5 (or Figs. 7 to 9), will extend into the interior of the storage region 16, 17. Naturally, the height h3 shown in Figures 6c) and d) will correspondingly be greater.

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7a) and b) show cross sections of a spacer profile according to a fourth embodiment. The fourth embodiment differs from the first embodiment in that the bend is not a bend of 90 ° but a bend of 180 °. Therefore, the bending portion of the elongated portion that is part of the profile 31d. 32d. it does not extend in the transverse direction X but extends in the height direction Y. Thus, the three-sided closure of the profile body material portion extends into the receiving regions 16, 17, although only one bend is present. Thus, as in the previous embodiments, when bending the spacer profile with compression, a bulk element is present which can be effectively acting as a bulk element substantially incompressible.

Figures 8a) and b) show cross sections of a spacer profile according to a fifth embodiment. The fifth embodiment differs from the fourth embodiment in that the bending radius of curvature of the profile 31e, 32e is smaller than in the fourth embodiment.

Figures 9a) and 9b) show cross sections of a spacer profile according to a sixth embodiment. The sixth embodiment differs from the first to fifth embodiments shown in Figures 4 to 8 in that the profiles 31f, 32f comprise a first bend of about 45 ° towards the inside, then a bend of about 45 ° in the opposite direction, and finally a bend 180 °, so that the profile of the foil surrounds the body portion of the spacer profile on three sides.

10a) and 10b) show comparative examples of spacer profiles having a W-configuration and a U-configuration and which do not include a profiled elongated portion. Fig. 10c) shows a table with the values measured in the test arrangement according to Fig. 3b). In the test arrangement of Fig. 3b), the spacer profile lies on two supports separated by a distance L, whereby the deflection D is measured compared to the ideal non-deflection profile (i.e., a straight line between the two support points). For the data shown in the table of Fig. 10c), L = 2000 mm, bl = 15.3 mm, hl = 7 mm for the W configuration and bl = 13.3 mm, hl = 8.4 mm for the U configuration. The same material, same material thickness, etc. were used for all profile designs, etc. Data is based in part on measurements and in part on calculations.

The reduction in deflection of all of the embodiments shown in FIGS. 4 to 9 is significant, compared to the spacer profiles of FIG. 10, 20% or more.

Figures 11a) and b) show cross sections of a spacer profile according to a seventh embodiment. The seventh embodiment differs from the sixth embodiment in that the 31g and 32g profiles do not have a 180 ° bend.

It was also determined for the spacer profiles of the invention that wrinkle formation in bends, as schematically indicated in Fig. 3c), for all the embodiments shown in Figs. 4 to 9 and 11, is compared to the comparative examples of Figs. 10 significantly suppressed. In other words, the number of wrinkles and / or wrinkle length was less on the bent spacing profiles of the invention. The behavior of the respective wrinkle distance profiles, which was evaluated based on the number of wrinkles and / or wrinkle length, is presented in the table in Figure 12, where "+" means less wrinkles and "++" means significantly less wrinkles compared to the comparative example ( Fig. 10).

Naturally, further modifications of the profile of the elongated portions 31, 32 are also conceivable.

Significant reduction in wrinkle formation means that better adhesion and sealing of the inside of the window panes can be achieved. Reducing the deflection then means that, in particular for large spacer profiles, i.e. for a large window width, to attach the spacer profile so that the deflection is not visible, less work is required.

Making a spacer profile frame from a spacer profile according to one of the above-described embodiments also results in the final obtained frame being closer to the ideal shape shown in Fig. 2 than to the less ideal shape shown in Fig. 3a). The spacer profile frame, whether made in one piece by bending, preferably by cold bending, or made from several straight individual pieces connected by corner connectors, is used in the insulating window unit shown in Fig. 1. In Fig. 1, the elongated portions are not shown.

As shown in Fig. 1, the side walls 11, 12 formed as attachment bases are glued to the inner sides of the window panes 51, 52 by means of adhesive material (primary sealant)

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61, e.g., a butyl sealant based on polyisobutylene. Thus, the interspace 53 between the window panes is defined by two panes 51, 52 and a spacer 50. The inner side of the spacer 50 points into the interspace 53 between the panes 51, 52. On the side that faces away from the interspace 53 between the panes in the height direction. Y, a mechanically stabilizing sealant (secondary sealant), for example based on polysulfide, polyurethane, or silicone, is introduced into the remaining, free space between the inside of the window panes to fill the void. This sealant also protects the diffusion barrier layer from mechanical or other corrosive / degrading effects.

As mentioned above, the rigid connection of the diffusion barrier film 30 to the profile body 10 is achieved by coextrusion. According to the embodiments shown in Figs. 4, 5, 7, 9 and 9, with the material, preferably the synthetic material, the profile body contacts more than one side of the diffusion barrier profile. In particular, when using synthetic material and metal, a strong bond, i.e. adhesion, between the metal and synthetic material can be provided by an adhesive material that is applied to the metal foil.

A method for producing a spacer profile 50 that can be used as a spacer profile frame that is suitable for fastening to and / or along the edge region of an insulating window unit so as to form and maintain the space 53 between the window panes 51, 52 one or more chambers 20 in a profile body 10 made of synthetic material. Either simultaneously or subsequent to the chamber forming step, a metal foil 30 may be placed on and / or at least three sides of the profile body 10 so that, after bending, the fourth, uncovered side of the profile body 10 faces in the assembled insulating window unit into the interspace 53 between Tables 51, 53, wherein the metal foil causes the at least three coated sides to be substantially gas impermeable, while the fourth side of the profile body 10 is gas permeable. Preferably, both ends of the metal foil 30 are formed into a profile 31a-g. 32a-g. which has at least one edge or bend.

Each of the various features and teachings described above may be used alone or together with other features and teachings to provide improved spacers, insulating window units and methods for designing, manufacturing and using these profiles and units. Representative examples of the invention which utilize many of these additional features and teachings, both individually and in combination, are described in detail above with reference to the accompanying drawings. This detailed description is intended solely to explain to the person skilled in the art further details of the implementation of preferred aspects of the invention, and is not intended to limit the scope of the invention in any way. Thus, combinations of features and steps explained in the detailed description are not needed in the broader sense for the practice of the invention and are given only for the purpose of describing particular representative examples of the invention.

Further, the various features of representative examples and dependent claims may be combined with methods that are not specifically and openly numbered to provide other useful embodiments of the invention. In addition, it should be noted that all of the features set forth in the description and / or claims are considered to be separate and independent of each other for purposes of both the original description and for the purpose of limiting the subject matter of the invention independently of the composition of features in the embodiments and / or claims. It should also be openly noted that for purposes of both the original description and the object limitation, all ranges of values or indications of entity groups include all possible mean values or mean entities.

The contents of US Patent Nos. 5,313,761, 5,675,944, 6,038,825, 6,068,720 and 6,339,909, US Patent Publication Nos. 2005-0100691 and US Patent Application No. 11 / 038,765 provide additional useful teachings that may be combined with the teachings of this document to provide other embodiments of the invention. publications are incorporated herein by reference as if they were fully interpreted herein.

Claims (22)

A spacer profile (50) for a spacer profile frame, which is configured to be fastened to and / or along the peripheral edge of an insulating window unit, to form and maintain an interspace (53) between the window panes (51, 52), The longitudinal direction (Z) comprises a first width (b1) in a transverse direction (X) that is perpendicular to the longitudinal direction (Z), a first height (hl) in a height direction (Y) that is perpendicular to the longitudinal direction (Z), and a transverse direction (X), wherein in the height direction (Y) the spacer profile comprises an inner side (13) which is arranged so as to adjoin the interspace (53) between the window panes (51, 52) when assembled. the spacer profile (50) comprises: a profile body (10) which is formed of a first material and defines a chamber (20) therein for storing the hygroscopic material, wherein the chamber: (i) is laterally defined transversely by the side walls (11, 12), (ii) comprises a second the height (h2) in the height direction (Y) and (iii) is formed such that it is not in the height direction (Y) on the inner wall (13) of the diffusion-resistant profile body (10) and the one-piece diffusion barrier foil (30); which is formed of a second material having a first thickness (d1) of less than 0.3 mm, wherein the film (30) is rigidly connected to the profile body (10) such that the film is located on the outer wall (14) of the chamber (20) ) facing away from the inner wall (13) of the chamber (20) and continuously extending to a height direction (Y) in which it is positioned substantially along the height of the chamber (20), characterized in that the diffusion barrier foil (30) cross section perpendicular to the longitudinal direction (Z), contains on each from its two lateral edges a profile (31g, 32a-g) which is fully contained in the receiving region (16, 17), the receiving region (16, 17) abutting in the height direction (Y) to the inner wall (13) of the spacer The profile (50) and is arranged in the height direction (Y) from the inner wall (13) away from the interspace (53) between the window panes (51, 52) and comprises a third height (h3) which is less than or equal to 0.4 (hl). Spacer (50) according to claim 1, characterized in that the elongated portion (31, 32) extends from the outside of the respective side wall (11, 12) towards the interior of the spacer in the transverse direction (X) over a length ( 11) which is greater than or equal to 0.1 (b1) and less than or equal to 0.3 (b1). Spacer (50) according to claim 1 or 2, characterized in that the third height (h3) is less than or equal to 0.2 (hl) and in particular less than or equal to 0.1 (hl), and the elongated mass. The portion (31, 32) comprises at least about 10% by weight of the remaining portion of the diffusion barrier film (30) that is above the centerline of the spacer in the height direction. A spacer profile (50) for a spacer profile frame that is configured to be fastened to and / or along the peripheral edge of an insulating window unit to form and maintain an interspace (53) between the window panes (51, 52), the longitudinal direction (Z) comprises a first width (b1) in a transverse direction (X) that is perpendicular to the longitudinal direction (Z), a first height (hl) in a height direction (Y) that is perpendicular to the longitudinal direction (Z), and a transverse direction (X), wherein in the height direction (Y) the spacer (50) comprises an inner wall (13) which is arranged so that, in the assembled state of the spacer profile frame, it adjoins the interspace (53) between the window panes (51, 52) ), the spacer profile (50) comprising: a profile body (10) which is formed of a first material and defines a chamber (20) therein for storing the hygroscopic material, wherein the chamber: (i) is laterally defined transversely by the side walls (11, 12), (ii) comprises a second the height (h2) in the height direction (Y) and (iii) is such that it is not diffusion-resistant in the height direction (Y) on the inner wall (13) of the profile body (10), and 23864 U1 a one-piece diffusion barrier film (30) formed of a second material having a first thickness (dl) of less than 0.3 mm, wherein the film (30) is rigidly attached to the profile body (10) such that is located on the outer wall (14) of the chamber (20) facing away from the inner wall (13) of the chamber (20) and continuously passes into the height direction (Y) in which it is located substantially along the height of the chamber (20); wherein the corresponding side walls (11, 12) are formed as an attachment base for attaching the inside of the window panes, the diffusion barrier foil (30), viewed in cross-section perpendicular to the longitudinal direction (Z), comprises at least one of its side edges (31a-g, 32a-g), which is fully contained in the receiving region (16, 17) adjacent the inner wall (13) of the spacer (50) in the height direction (Y) and arranged in the height direction (Y). ) from the inner wall (13) p from the interstice (53) between the window panes (51, 52), and the mass of the elongate portion (31, 32) comprises at least about 20% of the mass of the remaining portion of the diffusion barrier film that is above the centerline of the spacer. Spacer (50) according to claim 4, characterized in that the mass of the elongated portion (31, 32) comprises at least 50% by weight of the remaining portion of the diffusion barrier film above the center line of the spacer in the height direction. Spacer (50) according to any one of the preceding claims, characterized in that the profile (31a-g, 32a-g) of the elongated portion (31, 32) comprises one or more bends. Spacer (50) according to any one of the preceding claims, characterized in that the first material is a synthetic material, preferably a polyolefin and even more preferably a polypropylene, and / or the second material is a metal, preferably stainless steel or steel having corrosion protection. of tin (tin) or zinc. Spacer (50) according to any one of the preceding claims, characterized in that the first and second material are selected such that the spacer profile (50) is cold bendable. Spacer (50) according to any one of the preceding claims, characterized in that the profile (31b, d, e, f; 32b, d, e, f) of the elongated portion (31, 32) surrounds the body segment (3) on three sides. 10) profile. A spacer profile (50) for a spacer profile frame that is configured to be fastened to and / or along the peripheral edge of the insulating window unit, to form and maintain an interspace (53) between the window panes (51, 52), the spacer profile (50). ) contains: a spacer (50) body (10) made of synthetic material and defining a chamber (20) for storing hygroscopic material therein, a metal foil (30) that surrounds the body (10) on three sides so that in a bent and / or or in the assembled state of the spacer profile (50), the inner side of the body (10) which is not surrounded adjoins the interspace (53) between the window panes (51, 52), the inner side of the body (10) comprising openings (15) adapted to facilitate the exchange of moisture between the hygroscopic material housed in the chamber (20) and the interspace (53) between the window panes (51, 52), characterized in that the metal foil (30) comprises at each end a profile (31a-g, 32a-g) which is located near the interspace (53) arranged between the window panes (51, 52) and has at least one edge or bend. Spacer (50) according to claim 10, characterized in that the profile (31c, 32c) comprises a bending adjoining portion, which portion is exposed on the inner side of the body (10) of the spacer profile (50). -10GB 23864 U1 Spacer (50) according to claim 10, characterized in that the profile (31a, b, d to g; 32a, b, d to g) is completely surrounded by the body (10) of the spacer profile (50). Spacer (50) according to any one of the preceding claims, characterized in that the spacer profile body (10) defines a chamber (20) for storing hygroscopic material which is laterally defined by the side walls (11, 12). . Spacer (50) according to claim 13, characterized in that the corresponding side walls (11, 12) are designed as connecting bases for connecting the inside of the window panes. Spacer (50) according to any one of the preceding claims, characterized in that the synthetic material is a polyolefin, such as polypropylene. Spacer (50) according to any one of the preceding claims, characterized in that the metal is stainless steel or steel having corrosion protection made of tin (tin coating) or zinc. Spacer (50) according to any one of the preceding claims, characterized in that the metal foil (30) has a first thickness (d1) of greater than or equal to 0.03 mm and less than or equal to 0.20 mm. Spacer (50) according to any one of the preceding claims, characterized in that the first thickness (d1) of the metal foil (30) is greater than or equal to 0.03 mm and less than or equal to 0.10 mm. Spacer (50) according to any one of the preceding claims, characterized in that the spacer profile (50) is cold bendable. Spacer (50) according to any one of the preceding claims, wherein the mass of the elongated portion (31, 32) comprises at least about 10% by weight of the remainder of the metal foil (30) that is above the centerline of the spacer profile (50). in the height direction. Spacer (50) according to any one of the preceding claims, characterized in that the mass of the elongated portion (31, 32) comprises at least about 50% by weight of the remainder of the metal foil (30) that is above the centerline of the spacer profile (50). in the height direction. An insulating window unit, comprising: at least two window panes (51, 52) arranged opposite one another with a spacing therebetween so as to form an interspace (53) between the panes (51, 52), characterized in that the insulating window unit comprises a spacer profile frame formed of a spacer The profile (50) of any one of claims 1 to 21, which at least partially defines an interspace (53) between the window panes (51, 52), wherein the attachment bases of the spacer profile (50) are glued by diffusion resistant material (61) substantially along its entire length and height to the inner side of the window pane (51, 53) facing them, and the remaining void between the inner sides of the window pane (51, 52) on the side of the spacer profile frame and the adhesive material (61) the interspace (53) separated by a spacer profile frame, it is filled with a mechanically stabilizing sealing material (62).